Nanodesign of new self-assembling core-shell gellan-transfersomes loading baicalin and in vivo evaluation of repair response in skin

6533b82afe1ef96bd128c41d

RESEARCH PRODUCT

Nanodesign of new self-assembling core-shell gellan-transfersomes loading baicalin and in vivo evaluation of repair response in skin

Donatella Valenti Maria Manconi Claudia Cencetti Octavio Díez-sales Davide Demurtas Maria Letizia Manca Pietro Matricardi Carla Caddeo Francisco J. Aranda María Carmen Terencio Juan C. Gómez-fernández Amparo Nácher Silvia Mir-palomo Anna Maria Fadda

subject

3003 Swine Pharmaceutical Science Medicine (miscellaneous)02 engineering and technology 01 natural sciences Mice chemistry.chemical_compound Drug Delivery Systems materials science (all)skin delivery General Materials Science Skin chemistry.chemical_classification Skin repair Small-angle X-ray scattering Bilayer Vesicle Anti-Inflammatory Agents Non-Steroidal Polysaccharides Bacterial Polymer 021001 nanoscience & nanotechnology medicine.anatomical_structure Molecular Medicine Female 0210 nano-technology transfersomes Skin Absorption Biomedical Engineering gellan Bioengineering Administration Cutaneous 010402 general chemistry In vivo studies Dermis In vivo SAXS analysis medicine Animals gellan; In vivo studies; rheological studies; SAXS analysis; skin delivery; transfersomes; bioengineering; medicine (miscellaneous); molecular medicine; biomedical engineering; materials science (all); 3003 rheological studies Flavonoids Inflammation Wound Healing 0104 chemical sciences Animals Newborn chemistry Liposomes Biophysics Nanoparticles Baicalin

description

Gellan nanohydrogel and phospholipid vesicles were combined to incorporate baicalin in new self-assembling core-shell gellan-transfersomes obtained by an easy, scalable method. The vesicles were small in size (~107 nm) and monodispersed (P.I. ≤ 0.24), forming a viscous system (~24 mPa/s) as compared to transfersomes (~1.6 mPa/s), as confirmed by rheological studies. Gellan was anchored to the bilayer domains through cholesterol, and the polymer chains were distributed onto the outer surface of the bilayer, thus forming a core-shell structure, as suggested by SAXS analyses. The optimal carrier ability of core-shell gellan-transfersomes was established by the high deposition of baicalin in the skin (~11% in the whole skin), especially in the deeper tissue (~8% in the dermis). Moreover, their ability to improve baicalin efficacy in anti-inflammatory and skin repair tests was confirmed in vivo in mice, providing the complete skin restoration and inhibiting all the studied inflammatory markers.

year	journal	country	edition	language
2017-03-06

https://infoscience.epfl.ch/record/259443